U.S. patent number 7,042,354 [Application Number 10/316,978] was granted by the patent office on 2006-05-09 for tamper-resistant electronic seal.
This patent grant is currently assigned to Hi-G-Tek Ltd.. Invention is credited to Micha Auerbach, Rony Cohen, Arcadi Genin, Ran Sender.
United States Patent |
7,042,354 |
Auerbach , et al. |
May 9, 2006 |
Tamper-resistant electronic seal
Abstract
A tamper-resistant remotely monitorable electronic seal
including a shaft portion, a sensor, a socket arranged to engage
the shaft portion and the sensor in a monitorable manner and a
wireless communicator associated with at least one of the shaft
portion, the sensor and the socket and being operative to provide a
remotely monitorable indication of at least one monitorable event,
the sensor being operative to sense application of force to the
electronic seal in an attempt to separate the shaft portion from
the socket and to indicate the application of force as one of the
at least one monitorable event.
Inventors: |
Auerbach; Micha (Maccabim,
IL), Cohen; Rony (Zoran, IL), Genin;
Arcadi (Bat Yam, IL), Sender; Ran (Tel Aviv,
IL) |
Assignee: |
Hi-G-Tek Ltd. (Or-Yehuda,
IL)
|
Family
ID: |
32506033 |
Appl.
No.: |
10/316,978 |
Filed: |
December 11, 2002 |
Prior Publication Data
|
|
|
|
Document
Identifier |
Publication Date |
|
US 20040113782 A1 |
Jun 17, 2004 |
|
Current U.S.
Class: |
340/539.31;
340/572.8; 340/686.4; 340/568.2 |
Current CPC
Class: |
G08B
13/1445 (20130101); G09F 3/0335 (20130101); G09F
3/0317 (20130101); G08B 13/149 (20130101) |
Current International
Class: |
G08B
1/08 (20060101) |
Field of
Search: |
;340/539.31,542,572.9,693.5,568.4,568.1,571 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: Lee; Benjamin C.
Attorney, Agent or Firm: Ladas and Parry LLP
Claims
The invention claimed is:
1. A tamper-resistant remotely monitorable electronic seal
comprising: a shaft portion; a sensor; a socket arranged to engage
said shaft portion and said sensor in a monitorable manner; and a
wireless communicator associated with at least one of said shaft
portion, said sensor and said socket and being operative to provide
a remotely monitorable indication of at least one monitorable
event, said sensor being operative to sense application of a first
force to said electronic seal in an attempt to separate said shaft
portion from said socket and to indicate said application of said
first force as one of said at least one monitorable event, said
shaft portion, said socket and said sensor being constructed such
that upon application of a second force which is not sufficiently
large to separate said shaft portion from said socket, said
application of said second force is indicated as one of said at
least one monitorable event, even though said shaft portion remains
mechanically engaged with said socket; a sensing cap mounted on
said shaft portion and supporting said sensor; and at least one
retaining ring engaging said socket and said shaft portion for
retaining said sensing cap in said socket independently of said
shaft portion and wherein said shaft portion includes frangible
portions, whereby application of said first and second forces
causes breakage at the respective frangible portions, which
breakage is one of said at least one monitorable event.
2. A tamper-resistant remotely monitorable electronic seal
according to claim 1 and wherein said sensor is also operative to
sense disengagement of said shaft portion and said sensor and to
indicate said disengagement as one of said at least one monitorable
event.
3. A tamper-resistant remotely monitorable electronic seal
according to claim 1 and wherein said sensor comprises a
temperature sensor which is operative to monitor heating of said
socket and to indicate heating thereof beyond a predetermined
threshold as one of said at least one monitorable event.
4. A tamper-resistant remotely monitorable electronic seal
according to claim 1 and wherein said socket comprises a single-use
socket.
5. A tamper-resistant remotely monitorable electronic seal
according to claim 1 and wherein said socket is a mechanically
lockable socket.
6. A tamper-resistant remotely monitorable electronic seal
according to claim 1 and wherein said socket comprises a
transponder and said shaft portion comprises an inductor, said
transponder being operative to transmit information relating to
said socket, via said inductor, to said wireless communicator.
7. A tamper-resistant remotely monitorable electronic seal
according to claim 6 and wherein said transponder comprises an RF
transponder and said inductor comprises an RF receive/transmit
inductor and wherein said inductor communicates via at least one
conductor extending through said shaft portion to said wireless
communicator.
8. A tamper-resistant remotely monitorable electronic seal
according to claim 1 and wherein said shaft portion includes at
least one conductor which is interrupted in response to
disengagement of said shaft portion and said sensor and wherein
said disengagement results in one of said at least one monitorable
event.
9. A tamper-resistant remotely monitorable electronic seal
according to claim 8 and wherein there is associated with said at
least one conductor at least one propinquity switch which is
operated by an actuator associated with said socket whereby when
said shaft portion is separated from said socket said switch is
opened and said at least one conductive path is broken, producing
one of said at least one monitorable event.
10. A tamper-resistant remotely monitorable electronic seal
according to claim 9 and wherein said at least one propinquity
switch comprises at least one magnetic switch and said actuator
comprises a magnet.
11. A tamper-resistant remotely monitorable electronic seal
according to claim 1 and wherein said communicator is located in a
sensing circuitry and communicator housing integrally formed with
said shaft portion.
12. A tamper-resistant remotely monitorable electronic seal
according to claim 1 and wherein: said shaft portion comprises a
frangible shaft portion having a lockable portion; and said socket
comprises a locking element arranged to engage said lockable
portion in a removable manner, whereby disengagement of said
locking element and said shaft portion results in one of said at
least one monitorable event.
13. A tamper-resistant remotely monitorable electronic seal
according to claim 12 and wherein said sensor comprises a
temperature sensor which is operative to monitor heating of said
socket and to indicate heating thereof beyond a predetermined
threshold as one of said at least one monitorable event.
14. A tamper-resistant remotely monitorable electronic seal
according to claim 12 and wherein said socket comprises a
transponder and said shaft portion comprises an inductor, said
transponder being operative to transmit information relating to
said socket, via said inductor, to said wireless communicator.
15. A tamper-resistant remotely monitorable electronic seal
according to claim 14 and wherein said transponder comprises an RF
transponder and said inductor comprises an RF receive/transmit
inductor and wherein said inductor communicates via at least one
conductor extending through said shaft portion to said wireless
communicator.
Description
FIELD OF THE INVENTION
The present invention relates to electronic seals generally and
more particularly to tamper-resistant electronic seals.
BACKGROUND OF THE INVENTION
The following U.S. Patents are believed to be representative of the
prior art:
U.S. Pat. Nos. 4,750,197; 5,056,837; 5,097,253; 5,127,687;
5,169,188; 5,189,396; 5,406,263; 5,421,177; 5,587,702; 5,656,996
and 6,069,563.
SUMMARY OF THE INVENTION
The present invention seeks to provide an improved electronic
seal.
There is thus provided in accordance with a preferred embodiment of
the present invention a tamper-resistant remotely monitorable
electronic seal including a shaft portion, a sensor, a socket
arranged to engage the shaft portion and the sensor in a
monitorable manner and a wireless communicator associated with at
least one of the shaft portion, the sensor and the socket and being
operative to provide a remotely monitorable indication of at least
one monitorable event, the sensor being operative to sense
application of force to the electronic seal in an attempt to
separate the shaft portion from the socket and to indicate the
application of force as one of the at least one monitorable
event.
Preferably, the sensor is also operative to sense disengagement of
the shaft portion and the sensor and to indicate the disengagement
as one of the at least one monitorable event.
In accordance with another preferred embodiment of the present
invention, the tamper-resistant remotely monitorable electronic
seal also includes a sensing cap mounted on the shaft portion and
supporting the sensor. Additionally or alternatively, the sensor
includes a temperature sensor which is operative to monitor heating
of the socket and to indicate heating thereof beyond a
predetermined threshold as one of the at least one monitorable
event.
In accordance with another preferred embodiment of the present
invention, the tamper-resistant remotely monitorable electronic
seal also includes at least one retaining ring engaging the socket
and the shaft portion for retaining the sensing cap in the socket
independently of the shaft portion and wherein the shaft portion
includes a frangible portion, whereby application of a force to
separate the shaft portion from the socket causes breakage between
the sensing cap and the shaft portion at the frangible portion,
which breakage is one of the at least one monitorable event.
In accordance with still another preferred embodiment of the
present invention, the socket includes a single-use socket.
Alternatively, the socket is a mechanically lockable socket.
In accordance with another preferred embodiment of the present
invention, the socket includes a transponder and the shaft portion
includes an inductor, the transponder being operative to transmit
information relating to the socket, via the inductor, to the
wireless communicator. Preferably, the transponder includes an RF
transponder and the inductor includes an RF receive/transmit
inductor and wherein the inductor communicates via at least one
conductor extending through the shaft portion to the wireless
communicator.
In accordance with yet another preferred embodiment of the present
invention, the shaft portion includes at least one conductor which
is interrupted in response to disengagement of the shaft portion
and the sensor and wherein the disengagement results in one of the
at least one monitorable event.
Preferably, the communicator is located in a sensing circuitry and
communicator housing integrally formed with the shaft portion.
In accordance with still another preferred embodiment of the
present invention, there is associated with the at least one
conductor at least one propinquity switch which is operated by an
actuator associated with the socket whereby when the shaft portion
is separated from the socket the switch is opened and the at least
one conductive path is broken, producing one of the at least one
monitorable event. Preferably, the at least one propinquity switch
includes at least one magnetic switch and the actuator includes a
magnet.
Further in accordance with another preferred embodiment of the
present invention, the shaft portion includes a frangible shaft
portion having a lockable portion and the socket includes a locking
element arranged to engage the lockable portion in a removable
manner, whereby disengagement of the locking element and the shaft
portion results in one of the at least one monitorable event.
BRIEF DESCRIPTION OF THE DRAWINGS
The present invention will be understood and appreciated more fully
from the following detailed description, taken in conjunction with
the drawings in which:
FIGS. 1A and 1B are simplified pictorial illustrations of a
press-fit electronic seal assembly constructed and operative in
accordance with a preferred embodiment of the present
invention;
FIG. 1C is a sectional illustration of a portion of the press-fit
electronic seal of FIGS. 1A and 1B;
FIGS. 2A, 2B and 2C are simplified pictorial illustrations of
different types of breaks produced in the press-fit electronic seal
of FIGS. 1A 1C;
FIGS. 2D, 2E and 2F are simplified pictorial illustrations showing
the result of another attempt to tamper with the press-fit
electronic seal of FIGS. 1A 1C;
FIGS. 3A and 3B are simplified pictorial illustrations of a
lockable electronic seal constructed and operative in accordance
with a preferred embodiment of the present invention in respective
unlocked and locked operative orientations;
FIGS. 4A and 4B are simplified pictorial illustrations of a
lockable electronic seal constructed and operative in accordance
with another preferred embodiment of the present invention in
respective unlocked and locked operative orientations; and
FIGS. 5A, 5B and 5C are simplified pictorial illustrations of a
lockable electronic seal constructed and operative in accordance
with yet another preferred embodiment of the present invention in
three operative orientations.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
Reference is now made to FIGS. 1A, 1B and 1C, which are,
respectively, simplified pictorial illustrations and a sectional
illustration of a press-fit electronic seal constructed and
operative in accordance with a preferred embodiment of the present
invention.
As seen in FIGS. 1A, 1B and 1C, there is provided a
tamper-resistant electronic seal which preferably comprises a shaft
portion 10, which is integrally formed with or fixed to a sensing
circuitry and transceiver portion 12. Shaft portion 10 preferably
has a generally cylindrical configuration and terminates in a
press-fit tip 14, which includes a sensing cap 16 fixed within a
recess 17 formed at a forward end thereof and which adapted for
press-fit engagement with a socket 18. The press-fit engagement
between tip 14 of shaft portion 10 and socket 18 is preferably
constructed such that it is impossible to remove the press-fit tip
14 from the socket 18 without breaking the shaft portion 10. The
press-fit engagement between press-fit tip 14 and socket 18 is such
that the application of a low-level force to the socket 18 or the
shaft portion 10 causes part of the press-fit tip 14 including the
sensing cap 16 to separate from the shaft portion 10, as described
hereinbelow with reference to FIG. 2A.
Shaft portion 10 preferably includes weakened frangible portions
22, 24 and 25. Frangible portions 22, 24 and 25 typically have a
lesser thickness than the remainder of the shaft portion 10.
Frangible portion 22 is preferably located intermediate sensing
circuitry and transceiver portion 12 and most of shaft portion 10.
Frangible portions 24 and 25 are preferably located in shaft
portion 10 at a location adjacent tip 14. Typical locations of
frangible portions 22, 24 and 25 are illustrated in FIGS. 1A and
1B.
At least one conductive loop 26 preferably extends from sensing
circuitry and transceiver portion 12 through shaft portion 10,
preferably extending into recess 17, and is configured and mounted
in shaft portion 10, such that breakage of the shaft portion 10
produces a disconnection or significant change in the properties,
such as the electromagnetic, mechanical and/or thermal properties,
of the conductive loop 26. In accordance with a preferred
embodiment of the present invention, sensing cap 16 is attached to
press-fit tip 14 such that it is in contact, preferably electrical
contact, with conductive loop 26. Sensing cap 16 preferably
includes at least one sensor 28, such as a temperature sensor or
any other suitable sensor. Sensor 28 is preferably connected to
conductive loop 26, such as by crimping. Conductive loop 26 is
operative to transmit information from the sensor 28 to sensing
circuitry 30, forming part of sensing circuitry and transceiver
portion 12.
It is appreciated that, even though in the illustrated embodiment
sensor 28 is located on sensing cap 16, one or more sensors 28 may
alternatively be located at any suitable location in communication
with conductive loop 26.
Socket 18 also preferably comprises a sealing ring 32, which
preferably engages a recess defining frangible portion 24, and a
sealing ring 34, which preferably engages a recess defining
frangible portion 25. Sealing rings 32 and 34 preferably provide
press-fit engagement between press-fit tip 14 and socket 18.
In accordance with a preferred embodiment of the present invention,
a transceiver, preferably an RF transceiver 38, also forms part of
sensing circuitry and transceiver portion 12. Sensing circuitry 30
preferably is electrically coupled to conductive loop 26 and senses
the integrity thereof. In another preferred embodiment, sensing
circuitry 30 is also operative to receive indications from sensor
28, such as changes in temperature, which might be caused, for
example, by someone attempting to tamper with the electronic seal
by heating the socket 18. Alternatively, sensing circuitry 30 may
be operative to receive indications of engagement or disengagement
of shaft portion 10 with respect to sealing rings 32 and 34 or
socket 18.
Transceiver 38 receives an output from sensing circuitry 30, which
is operative to provide transmitted information indicating whether
the conductive loop 26 is intact as well as other information
received from sensor 28 via conductive loop 26. Conventional
wireless monitoring circuitry (not shown) may be employed to
receive information which is transmitted by RF transceiver 38
indicating tampering with the seal, which results in breakage of
the conductive loop 26 and/or any other information received from
sensor 28, such as heating of the socket 18 or engagement or
disengagement of the shaft portion 10.
In accordance with another preferred embodiment, sealing ring 34
includes at least one engagement protrusion 40 and frangible
portion 25 includes at least one corresponding engagement recess
42. In this embodiment, frangible portion 25 is locked by sealing
ring 34, such that a low level force causes the disconnection of
the sensing cap 16 and the part of tip 14 adjacent thereto from the
shaft portion 10, as described hereinbelow with reference to FIG.
2A. Alternatively, at least one engagement protrusion (not shown)
may be located in socket 18 which engages at least one engagement
slot (not shown) located in sensing cap 16. The insertion of
engagement protrusion 40 into engagement recess 42 preferably locks
the sensing cap 16 into the socket 18, such that a low level force
causes the disconnection of the sensing cap 16 from shaft portion
10, as described hereinbelow with reference to FIG. 2A. Engagement
protrusion 40 may be flexible to provide enhanced ease of
engagement with engagement location 42. Alternatively, engagement
protrusion 40 and corresponding engagement recess 42 may be
obviated.
Reference is now made to FIGS. 2A, 2B and 2C, which are simplified
pictorial illustrations of various different types of breaks
produced in the press-fit electronic seal of FIGS. 1A 1C by
tampering therewith. As noted above, application of force to the
seal of FIGS. 1A 1C in an attempt to separate shaft portion 10 from
socket 18 will not cause tip 14 to be disengaged from socket 18,
without first breaking the shaft portion 10. FIG. 2A shows that
applying a low level force, such as a rotational and/or lateral
force in an attempt to open the seal, results in a break at
frangible portion 25, causing a significant change in or
disconnection of conductive loop 26. Preferably, the sensing
circuitry 30 senses the change in conductive loop 26, even though
the seal remains intact as shaft portion 10 is engaged by sealing
ring 32.
FIG. 2B shows the results of applying a higher level force, such as
might be produced by attempting to remove socket 18 from shaft
portion 10, resulting in a break at frangible portion 24, producing
a disconnection in conductive loop 26.
FIG. 2C illustrates a break, which might be produced in a similar
manner as that shown in FIG. 2B, at the frangible portion 22. It is
seen that this break also typically produces a disconnection in
conductive loop 26.
It is appreciated that the breaks shown in FIGS. 2B and 2C, while
illustrated independently of the break produced in FIG. 2A, may be
preceded by the break in FIG. 2A when an attempt is made to tamper
with the electronic seal.
Reference is now made to FIGS. 2D, 2E and 2F which are simplified
pictorial illustrations of another attempt to tamper with the
press-fit electronic seal of FIGS. 1A 1C. As seen in FIG. 2D, an
attempt is made to separate socket 18 from shaft portion 10 of the
tamper-resistant electronic seal by sawing through socket 18 in the
region of tip 14 of shaft portion 10. FIG. 2E shows the resulting
cut in socket 18, where shaft portion 10 has not been cut. FIG. 2F
shows that the resulting separation of the socket 18 causes a break
along frangible portion 25, resulting in a disconnection of
conductive loop 26.
It is appreciated that any significant change in the properties,
such as the electromagnetic, mechanical and/or thermal properties,
or disconnection of conductive loop 26 is sensed by sensing
circuitry 30 and transmitted by RF transceiver 38.
Reference is now made to FIGS. 3A and 3B, which are simplified
pictorial illustrations of a lockable electronic seal constructed
and operative in accordance with a preferred embodiment of the
present invention in respective unlocked and locked operative
orientations.
As seen in FIGS. 3A and 3B, there is provided a tamper-resistant
reusable lockable electronic seal which preferably comprises a
shaft portion 50, which is integrally formed with or fixed to a
sensing circuitry and transceiver portion 52. Shaft portion 50
preferably has a generally cylindrical configuration and terminates
in a lockable tip 54, preferably formed with an undercut groove 56
which is adapted for lockable engagement therewith by a
corresponding locking element 58 forming part of a lock 60. Lock 60
defines a socket, which includes an actuator such as a magnet 61.
Lock 60 is here shown to be a key-operated lock, it being
appreciated that any other suitable type of lock may be employed.
The locking engagement between tip 54 of shaft portion 50 and
locking element 58 is preferably such that without first unlocking
the lock, it is impossible to remove the tip 54 from engagement
with the locking element 58 without breaking the shaft portion 50.
Lockable tip 54 is preferably attached to or integrally formed with
a sensing cap 62.
Shaft portion 50 preferably includes weakened frangible portions
63, 64 and 65, preferably having a lesser thickness than the
remainder of the shaft portion 50. Frangible portion 63 is
preferably located intermediate sensing circuitry and transceiver
portion 52 and most of shaft portion 50. Frangible portions 64 and
65 are preferably located in shaft portion 50 at a location
adjacent tip 54. Typical locations of frangible portions 63, 64 and
65 are illustrated in FIGS. 3A and 3B.
At least one conductive loop 66 preferably extends through shaft
portion 50 and is configured and mounted in shaft portion 50, such
that breakage of the shaft portion 50 produces a disconnection or
significant change in the properties, such as the electromagnetic,
mechanical and/or thermal properties, of the conductive loop 66.
Preferably connected in series with conductive loop 66 there is
provided a propinquity switch which is operated when the actuator
in the socket is separated therefrom by at least a threshold
distance. Preferably, the propinquity switch is a magnetically
operated switch 68, which is closed only when in propinquity to
magnet 61, such as when shaft portion 50 is in lockable or locked
engagement with lock 60.
It is appreciated that shaft portion 50 may comprise one or more
additional conductive loops, each of which may include a switch,
the operation of which may or may not be linked to the operation of
lock 60 and may provide additional information regarding the
integrity of the electronic seal.
Additionally, in accordance with a preferred embodiment of the
present invention, sensing cap 62 is in electrical contact with
conductive loop 66. Sensing cap 62 preferably includes at least one
sensor 70, such as a temperature sensor or other suitable sensor,
and communicates via conductive loop 66 with sensing circuitry
72.
It is appreciated that, even though in the illustrated embodiment
sensor 70 is located adjacent lockable tip 54, one or more sensors
70 may alternatively be located at any suitable location in
communication with conductive loop 66.
In accordance with a preferred embodiment of the present invention,
sensing circuitry 72 and an RF transceiver 74 are housed within
sensing circuitry and transceiver portion 52. Sensing circuitry 72
is electrically coupled to conductive loop 66 and senses the
integrity thereof. Additionally, sensing circuitry 72 is also
operative to receive indications from sensor 70, such as a change
in temperature, which might be caused, for example, by someone
attempting to tamper with the electronic seal by heating the lock
60. Transceiver 74 preferably receives an output from sensing
circuitry 72, which is operative to provide transmitted information
indicating whether the conductive loop 66 is intact as well as
information received from sensor 70 via conductive loop 66.
Conventional wireless monitoring circuitry (not shown) may be
employed to receive information which is transmitted by RF
transceiver 74 and indicates when the shaft portion 50 is located
in lockable or locked engagement with lock 60 and when the shaft
portion 50 is separated from lock 60 due to either tampering with
the seal, which may or may not result in breakage of the shaft
portion 50, or mutual disengagement of shaft portion 50 and lock 60
by using a key to unlock lock 60.
It is appreciated that the provision of the switch 68 enables
sensing circuitry 72 to sense when the shaft portion 50 is located
in lockable engagement with lock 60 and when the shaft portion 50
is separated from lock 60 for any reason, and allows for recording
of engagements and disengagements of shaft portion 50 and lock
60.
It is appreciated that the switch shown in the illustrated
embodiments of FIGS. 3A 3B can also be employed in the embodiments
of FIGS. 1A 2F.
Reference is now made to FIGS. 4A and 4B, which are simplified
pictorial illustrations of a lockable electronic seal constructed
and operative in accordance with a preferred embodiment of the
present invention in respective unlocked and locked operative
orientations.
As seen in FIGS. 4A and 4B, there is provided a tamper-resistant
reusable lockable electronic seal which preferably comprises a
shaft portion 150, which is integrally formed with or fixed to a
sensing circuitry and transceiver portion 152. Shaft portion 150
preferably has a generally cylindrical configuration and terminates
in a lockable tip 154, preferably formed with an undercut groove
156 which is adapted for lockable engagement therewith by a
corresponding locking element 158 forming part of a lock 160. Lock
160 defines a socket, which preferably includes an actuator such as
a magnet 161. Lock 160 is here shown to be a key-operated lock, it
being appreciated that any other suitable type of lock may be
employed. The locking engagement between tip 154 of shaft portion
150 and locking element 158 is preferably such that without first
unlocking the lock, it is impossible to remove the tip 154 from
engagement with the locking element 158 without breaking the shaft
portion 150. Lockable tip 154 is preferably attached to or
integrally formed with a sensing cap 162.
Shaft portion 150 preferably includes weakened frangible portions
163, 164 and 165, preferably having a lesser thickness than the
remainder of the shaft portion 150. Frangible portion 163 is
preferably located intermediate sensing circuitry and transceiver
portion 152 and most of shaft portion 150. Frangible portions 164
and 165 are preferably located in shaft portion 150 at a location
adjacent tip 154. Typical locations of frangible portions 163, 164
and 165 are illustrated in FIGS. 4A and 4B.
At least one conductive loop 166 preferably extends through shaft
portion 150 and is configured and mounted in shaft portion 150,
such that breakage of the shaft portion 150 produces a
disconnection or significant change in the properties, such as the
electromagnetic, mechanical and/or thermal properties, of the
conductive loop 166. Preferably connected in series with conductive
loop 166 there is provided a propinquity switch which is operated
when the actuator in the socket is separated therefrom by at least
a threshold distance. Preferably, the propinquity switch is a
magnetically operated switch 168, which is closed only when in
propinquity to magnet 161, such as when shaft portion 150 is in
lockable or locked engagement with lock 160.
It is appreciated that shaft portion 150 may comprise one or more
additional conductive loops, each of which may include a switch,
the operation of which may or may not be linked to the operation of
lock 160 and may provide additional information regarding the
integrity of the electronic seal.
Additionally, in accordance with a preferred embodiment of the
present invention, sensing cap 162 is in electrical contact with
conductive loop 166. Sensing cap 162 preferably includes at least
one sensor 170, such as a temperature sensor or other suitable
sensor, and communicates via conductive loop 166 with sensing
circuitry 172.
It is appreciated that, even though in the illustrated embodiment
sensor 170 is located adjacent lockable tip 154, one or more
sensors 170 may alternatively be located at any suitable location
in communication with conductive loop 166.
In accordance with a preferred embodiment of the present invention,
sensing circuitry 172 and an RF transceiver 174 are housed within
sensing circuitry and transceiver portion 152. Sensing circuitry
172 is electrically coupled to conductive loop 166 and senses the
integrity thereof. In another preferred embodiment, sensing
circuitry 172 is also operative to receive indications from sensor
170, such as a change in temperature, which might be caused, for
example, by someone attempting to tamper with the electronic seal
by heating the lock 160. Transceiver 174 preferably receives an
output from sensing circuitry 172, which is operative to provide
transmitted information indicating whether the conductive loop 166
is intact as well as information received from sensor 170 via
conductive loop 166.
Conventional wireless monitoring circuitry (not shown) may be
employed to receive information which is transmitted by RF
transceiver 174 and indicates when the shaft portion 150 is located
in lockable or locked engagement with lock 160 and when the shaft
portion 150 is separated from lock 160 due to either tampering with
the seal, which may or may not result in breakage of the shaft
portion 150, or mutual disengagement of shaft portion 150 and lock
160 by using a key to unlock lock 160.
As seen in FIGS. 4A and 4B, the tamper-resistant reusable lockable
electronic seal also preferably includes a transponder 180, such as
an RF transponder chip, and shaft portion 150 preferably includes
an inductor 182, such as an RF receive/transmit inductor.
Transponder 180 is operative to transmit information relating to
the lock 160, via the inductor 182 located in shaft portion 150, to
the sensing circuitry 172.
It is appreciated that the provision of the transponder 180 and the
inductor 182 enables sensing circuitry 172 to record information
transmitted by transponder 180 relating to the lock 160, such as,
for example, a serial number of the lock 160, and the fact that
shaft portion 150 is in locking engagement therewith. It is further
appreciated that the provision of the transponder 180 and the
inductor 182 enables sensing circuitry 172 to sense when the shaft
portion 150 is located in lockable or locked engagement with lock
160 or when the shaft portion 150 is separated from lock 160 for
any reason, and allows for recording of engagements and
disengagements of shaft portion 150 and lock 160.
Additionally, it is appreciated that the provision of the switch
168 enables sensing circuitry 172 to sense when the shaft portion
150 is located in lockable engagement with lock 160 and when the
shaft portion 150 is separated from lock 160 for any reason, and
allows for recording of engagements and disengagements of shaft
portion 150 and lock 160.
Reference is now made to FIGS. 5A, 5B and 5C, which are simplified
pictorial illustrations of a press-fit electronic seal constructed
and operative in accordance with yet another preferred embodiment
of the present invention.
As seen in FIGS. 5A and 5B, there is provided a tamper-resistant
reusable electronic seal which preferably comprises a reusable
shaft portion 250, which is integrally formed with or fixed to a
sensing circuitry and transceiver portion 252. Shaft portion 250
preferably has a generally cylindrical configuration and terminates
in a press-fit tip 254, which includes a sensing cap 256 fixed
within a recess (not shown) formed at a forward end thereof and
adapted for press-fit engagement with a single-use locking socket
258. The press-fit engagement between tip 254 of shaft portion 250
and single-use locking socket 258 is preferably constructed such
that it is impossible to remove the tip 254 from the single-use
locking socket 258 without breaking either the shaft portion 250 or
the single-use locking socket 258. The press-fit engagement between
press-fit tip 254 and single-use locking socket 258 is such that
the application of a low-level force to the single-use locking
socket 258 or the shaft portion 250 causes part of the press-fit
tip 254 including the sensing cap 256 to separate from the shaft
portion 250, similar to that described hereinabove with reference
to FIG. 2A.
Shaft portion 250 preferably includes a weakened frangible portion
263, located intermediate the sensing circuitry and transceiver
portion 252 and the tip 254. Frangible portion 263 typically has a
lesser thickness than the remainder of the shaft portion 250.
Additional frangible portions (not shown) may also be included at
suitable locations along shaft portion 250.
At least one conductive loop 266 preferably extends from sensing
circuitry and transceiver portion 252 through shaft portion 250 and
tip 254 and is configured and mounted in shaft portion 250, such
that breakage of the shaft portion 250 produces a disconnection or
significant change in the properties, such as the electromagnetic,
mechanical and/or thermal properties, of the conductive loop 266.
In accordance with a preferred embodiment of the present invention,
sensing cap 256 is attached to tip 254 such that it is in
electrical contact with conductive loop 266. Sensing cap 256
preferably includes at least one sensor 270, such as a temperature
sensor or any other suitable sensor. Sensor 270 is preferably
electrically connected to conductive loop 266 and is operative to
transmit information via conductive loop 266 to sensing circuitry
272.
It is appreciated that, even though in the illustrated embodiment
sensor 270 is located adjacent sensing cap 256, one or more sensors
270 may alternatively be located at any suitable location in
communication with conductive loop 266.
In accordance with a preferred embodiment of the present invention,
sensing circuitry 272 and a transceiver, such as an RF transceiver
274, are housed within sensing circuitry and transceiver portion
252. Sensing circuitry 272 preferably is electrically coupled to
conductive loop 266 and senses the integrity thereof. Additionally,
sensing circuitry 272 is preferably also operative to receive
indications from sensor 270, such as changes in temperature, which
might be caused, for example, by someone attempting to tamper with
the electronic seal by heating the single-use locking socket 258.
Alternatively, sensing circuitry 272 may be operative to receive
indications of engagement or disengagement of shaft portion 250
from single-use locking socket 258, as described hereinbelow.
Transceiver 274 receives an output from sensing circuitry 272,
which is operative to provide information indicating whether the
conductive loop 266 is intact as well as information received from
sensor 270 via conductive loop 266. Conventional wireless
monitoring circuitry (not shown) may be employed to receive
information which is transmitted by RF transceiver 274 indicating
tampering with the seal, which results in breakage of the
conductive loop 266 and/or any other information received from
sensor 270, such as heating or removal of the single-use locking
socket 258.
As seen in FIGS. 5A and 5B, the single-use locking socket 258
preferably includes a transponder 280, such as an RF transponder
chip, and shaft portion 250 preferably includes an inductor 282,
such as an RF receive/transmit inductor. Transponder 280 is
operative to transmit information relating to the single-use
locking socket 258, via the inductor 282 located in shaft portion
250, to the sensing circuitry 272. It is appreciated that the
provision of the transponder 280 and the inductor 282 enables
sensing circuitry 272 to record information about the single-use
locking socket 258, such as, for example, a serial number of the
single-use locking socket 258 and the fact that shaft portion 250
is in locking engagement therewith. It is further appreciated that
the provision of the transponder 280 and the inductor 282 enables
sensing circuitry 272 to sense when the shaft portion 250 is in
engagement with single-use locking socket 258 and when the shaft
portion 250 is separated from single-use locking socket 258.
FIG. 5C illustrates the breakage of single-use locking socket 258
and separation of reusable shaft portion 250.
It is appreciated that the switch shown in the illustrated
embodiments of FIGS. 3A 3B can also be employed in the embodiment
of FIGS. 5A 5C.
It will be appreciated by persons skilled in the art that the
present invention is not limited by what has been particularly
shown and described hereinabove. Rather the scope of the present
invention includes both combinations and subcombinations of the
various features described hereinabove as well as variations and
modifications which would occur to persons skilled in the art upon
reading the specification and which are not in the prior art.
* * * * *